CN114166905B - 68dB dynamic range potentiostat for electrochemical biosensing - Google Patents
68dB dynamic range potentiostat for electrochemical biosensing Download PDFInfo
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Abstract
The present disclosure relates to a 68dB dynamic range potentiostat for electrochemical biosensing, comprising: the device comprises a current reading circuit, a voltage bias circuit, a current compensation network, a 12-bit analog-to-digital converter (ADC), a 10-bit digital analog-to-digital converter (DAC), a power management unit, an SPI (serial peripheral interface) communication module and an electrochemical sensor; the current sensing circuit is connected with the current compensation network; a reference voltage pin of the power management unit is connected with the DAC (digital-to-analog converter) with 10 bits; a bias voltage pin of the power management unit is connected with the current compensation network; the WE end of the electrochemical sensor is respectively connected with the current sense amplifier and the current compensation network; the bias amplifier is connected between the 10-bit digital-to-analog converter DAC and the RE end and the CE end of the electrochemical sensor; the 10-bit digital-to-analog converter DAC and the 12-bit analog-to-digital converter ADC are respectively connected with the SPI communication module.
Description
Technical Field
The disclosure relates to the technical field of electrochemical biosensing, in particular to a 68dB dynamic range potentiostat for electrochemical biosensing.
Background
Electrochemical biosensing is widely used for analyzing and monitoring various human biomolecules or environmental harmful gases. It plays a crucial role in regular health status monitoring in daily life. Various electrochemical biosensing technologies in the prior art aim to detect substances such as blood sugar, dopamine, drug molecules, NO and/or CO. The design of an electrochemical sensor typically consists of three electrodes, including a Working Electrode (WE), a Reference Electrode (RE) and a Counter Electrode (CE), as shown in fig. 1. If a stimulus voltage V is applied between WE and RE cell The sensor will generate an associated redox current I according to the target concentration redox 。
Disclosure of Invention
The dynamic range potentiostat aims at solving the technical problem that the dynamic range potentiostat in the prior art can not meet the requirements of users on realizing rapid and accurate voltage control and current reading.
To achieve the above technical object, the present disclosure provides a 68dB dynamic range potentiostat for electrochemical biosensing, comprising:
the device comprises a current reading circuit, a voltage bias amplifier, a current compensation network, a 12-bit analog-to-digital converter (ADC), a 10-bit digital analog-to-digital converter (DAC), a power management unit, an electrochemical sensor and an SPI communication module;
the current sensing circuit is connected with the current compensation network;
the power supply management unit provides system power supply voltage;
the reference voltage V output by the power management unit REF The DAC is connected with the 10-bit digital-to-analog converter;
bias voltage P output by the power management unit bias Is connected with the current compensation network;
the WE end of the electrochemical sensor is respectively connected with the current reading circuit and the current compensation network;
the bias amplifier is connected between the 10-bit digital-to-analog converter DAC and the RE end and the CE end of the electrochemical sensor; the 10-bit digital-to-analog converter DAC and the 12-bit analog-to-digital converter ADC are respectively connected with the SPI communication module; the current compensation network is connected with the SPI communication module.
Furthermore, the current sensing circuit adopts a capacitive transimpedance amplifier (C-TIA) structure and comprises a chopper amplifier (AMP 1) and an integrating capacitor (C) F It also includes an integrating capacitor C F Switches connected in parallel for coupling the integrating capacitors C F And resetting periodically.
Further, the current compensation network specifically includes:
the current compensation logic control circuit comprises a 6-bit current digital-to-analog converter I-DAC, a current compensation logic control circuit and two complementary comparators which are connected;
the current sensing circuit is connected with the current compensation network through the two complementary comparators;
the 6-bit current digital-to-analog converter I-DAC is connected with a bias voltage pin of the power management unit;
and the WE end of the electrochemical sensor is connected with the 6-bit current digital-to-analog converter I-DAC.
Further, the current flowing into the integrator compensated by the current compensation network may be calculated as:
I i n=-(I WE -I DAC );
wherein I is WE Is a redox current, I, fed into a capacitive transimpedance amplifier C-TIA DAC Is the compensation current from the 6-bit current digital-to-analog converter I-DAC.
Further, in the present invention,
the control logic of the current compensation logic control circuit is expressed as:
β ctrl,n =β ctrl,n-1 +(β dir,H -β dir,L )Δβ adj
wherein, beta ctr1 Is a control signal, beta, of a 6-bit current digital-to-analog converter I-DAC dir,H Is a control signal, β, generated by an upper comparator dir,L Is a control signal generated by the lower comparator;
if the dynamic range of the redox current is within the linear range of the C-TIA, the output voltage of the C-TIA will remain at V H And V L Meanwhile, the upper comparator and the lower comparator both output low levels, and the current compensation network does not work at the moment;
if the redox current is too large, above the linear range of C-TIA, the C-TIA will saturate, yielding more than V H The upper comparator will generate a high level pulse beta dir,H Triggering a 6-bit current digital-to-analog converter I-DAC to increase the unit compensation current;
otherwise, if the redox current is too small, well below the offset current, the C-TIA will produce less than V L Output electricity ofThe voltage lower comparator will generate a high level pulse beta dir,L To trigger the 6-bit current digital-to-analog converter I-DAC to reduce the unit compensation current.
Further, the current sensing circuit adopts a capacitance feedback type transimpedance amplifier (C-TIA) structure, and the capacitance feedback type transimpedance amplifier comprises a chopper amplifier AMP1 and an integrating capacitor C F And an integrating capacitor C F Switches connected in parallel for feeding back the capacitance C F Periodic reset of (2);
further, the integral capacitance C of the C-TIA F Output voltage V of the C-TIA of 100pF out Calculated from the following formula:
where f is the frequency of the reset switch, C F Is the integrating capacitance, V, of C-TIA we Is the voltage at the WE terminal of the electrochemical sensor, I in Is the redox current fed to the capacitive transimpedance amplifier C-TIA.
Further, the current sense amplifier uses chopping switches to reduce the low frequency noise of the amplifier.
Further, the power management unit is composed of a low dropout regulator (LDO), and outputs: 1.8V supply voltage VDD, reference voltage V used by comparator in current compensation network H 、V L Reference voltage V of DAC of 10-bit digital-to-analog converter ref And bias voltage P of current compensation network I-DAC bias 。
The beneficial effect of this disclosure does:
the present disclosure provides a low power consumption large input dynamic range constant range potentiometer for electrochemical biosensing. Current compensation is used to extend the input range and chopper C-TIA is used for precision current sensing. Both the CA and CV modes are applicable to the detection process of different analytes. The current resolution of the chopper-stabilized potentiometer is 500pA, the dynamic range is 68dB, the linearity of R2 is 0.9993, and the power consumption is 105 muW. The potentiometer can meet the requirements of users on realizing rapid and accurate voltage control and current reading and has lower power consumption.
Drawings
FIG. 1 shows a schematic structure of a prior art three-electrode sensor for electrochemical biosensing;
fig. 2 shows a schematic structural diagram of a potentiometer according to a first embodiment of the present disclosure;
FIG. 3 shows a schematic diagram of a current compensation logic control circuit and a 6-bit current digital-to-analog converter I-DAC in a current compensation network of a potentiometer according to a first embodiment of the present disclosure;
fig. 4 shows a schematic structural diagram of a chopper amplifier in a current sensing circuit of a potentiometer according to a first embodiment of the present disclosure;
fig. 5 shows a schematic configuration diagram of a bias amplifier of the potentiometer according to the first embodiment of the present disclosure;
fig. 6 shows a schematic diagram of a component structure of a comparator in a current compensation network of a potentiometer according to a first embodiment of the disclosure;
fig. 7 shows a schematic diagram of a component structure of a comparator in a current compensation network of a potentiometer according to a first embodiment of the disclosure;
FIG. 8 is a schematic diagram showing the analog output voltage of the C-TIA as a function of the input current at the beginning or end of compensation according to the first embodiment of the disclosure;
FIG. 9 shows the redox currents measured from the ADC and the compensating I-DAC according to one embodiment of the present disclosure.
Detailed Description
Hereinafter, embodiments of the present disclosure will be described with reference to the accompanying drawings. It should be understood that these descriptions are illustrative only and are not intended to limit the scope of the present disclosure. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present disclosure.
Various structural schematics according to embodiments of the present disclosure are shown in the figures. The figures are not drawn to scale, wherein certain details are exaggerated and possibly omitted for clarity of presentation. The shapes of various regions, layers, and relative sizes and positional relationships therebetween shown in the drawings are merely exemplary, and deviations may occur in practice due to manufacturing tolerances or technical limitations, and a person skilled in the art may additionally design regions/layers having different shapes, sizes, relative positions, as actually required.
The first embodiment is as follows:
as shown in fig. 2:
the present disclosure provides a 68dB dynamic range potentiostat for electrochemical biosensing, comprising:
the device comprises a current reading circuit, a voltage bias amplifier, a current compensation network, a 12-bit analog-to-digital converter (ADC), a 10-bit digital-to-analog converter (DAC), a power management unit, an electrochemical sensor and an SPI communication module;
the current sensing circuit is connected with the current compensation network;
a reference voltage pin of the power management unit is connected with the DAC (digital-to-analog converter) with 10 bits;
the power supply management unit is connected with the current compensation network;
the WE end of the electrochemical sensor is respectively connected with the current sensing amplifier and the current compensation network;
the bias amplifier is connected between the 10-bit digital-to-analog converter DAC and the RE end and the CE end of the electrochemical sensor;
the 10-bit digital-to-analog converter DAC and the 12-bit analog-to-digital converter ADC are respectively connected with the SPI communication module.
Further, the current compensation network specifically includes:
the current compensation logic control circuit comprises a 6-bit current digital-to-analog converter I-DAC, a current compensation logic control circuit and two complementary comparators which are connected;
the current sensing circuit is connected with the current compensation network through the two complementary comparators;
the 6-bit current digital-to-analog converter I-DAC is connected with the power management unit;
the WE end of the electrochemical sensor is connected with the 6-bit current digital-to-analog converter I-DAC.
Further, the current flowing into the integrator compensated by the current compensation network may be calculated as:
I in =-(I WE -I DAC );
wherein I is WE Is a redox current, I, fed into a capacitive transimpedance amplifier C-TIA DAC Is the compensation current from the 6-bit current digital-to-analog converter I-DAC.
Further, the control logic of the current compensation logic control circuit is represented as:
β ctrl,n =β ctrl,n-1 +(β dir,H -β dir,L )Δβ adj
wherein beta is ctr1 Is a control signal, beta, of a 6-bit current digital-to-analog converter I-DAC dir,H Is a control signal, β, generated by an upper comparator dir,L Is a control signal generated by the lower comparator;
if the dynamic range of the redox current is within the linear range of the C-TIA, the output voltage of the C-TIA will remain at V H And V L Meanwhile, the upper comparator and the lower comparator both output low levels, and at the moment, the current compensation network does not work. If the redox current is too large, above the linear range of C-TIA, the C-TIA will saturate, yielding more than V H The upper comparator will generate a level pulse beta dir,H Triggering a 6-bit current digital-to-analog converter I-DAC to increase the unit compensation current;
otherwise, if the redox current is too small, well below the offset current, the C-TIA will produce less than V L The lower comparator will generate a high level pulse beta dir,L To trigger the 6-bit current digital-to-analog converter I-DAC to reduce the unit compensation current.
Further, the current sensing circuit includes a chopper amplifier AMP1 and an integrating capacitor C F And an integrating capacitor C F Switches connected in parallel for feeding back the capacitance C F Period of (2)Sexual reduction;
further, the integral capacitance C of the C-TIA F Output voltage V of the C-TIA of 100pF out Calculated from the following formula:
where f is the frequency of the reset switch, C F Is the integrating capacitance, V, of C-TIA we Is the voltage at the WE terminal of the electrochemical sensor, I in Is the redox current fed to the capacitive transimpedance amplifier C-TIA.
Further, the current sense amplifier uses chopping switches to reduce low frequency noise of the amplifier.
Further, the power management unit is composed of a low dropout regulator (LDO) and outputs: supply voltage VDD of 1.8V, reference voltage V used by comparator in current compensation network H 、V L Reference voltage V of DAC of 10-bit digital-to-analog converter ref And the bias voltage P of the current compensation network I-DAC bias 。
In particular, the amount of the solvent to be used,
due to the negative feedback of the amplifier, the voltages of WE and RE are fixed at V WE And V RE The above. All the current generated by the electrochemical sensor is fed to the on-chip integrating capacitor C F 。
Since the current variation is very small, the amplifier AMP1 employs a chopping technique to reduce low frequency noise and dc offset.
When measuring an analyte, the output of AMP1 is easily saturated because the redox current is unidirectional. Therefore, the present disclosure adds a switch in parallel with the integrating capacitor during design for periodic reset. The present disclosure is designed to compromise the problem of measured current frequency and potential data loss by using an off-chip 1kHz clock to control the reset switch.
Integrating capacitor C F Designed to be 100pF. The output voltage of AMP1 can be calculated as:
where f is the frequency of the reset switch, C F Is an integral capacitor, V we Is the voltage at the WE terminal of the electrochemical sensor, I in Is the redox current fed to the capacitive transimpedance amplifier C-TIA.
To reduce the power consumption of the system, the existing designs often use low voltage power supplies. However, designs that employ low voltage power supplies limit the output range of the C-TIA, which determines the maximum current that can be detected.
Furthermore, to obtain a large dynamic input range, an accurate ADC is required, but this will significantly increase the power consumption, area, and design difficulty of the overall system. Therefore, the present disclosure designs a current compensation circuit with an automatic input current tracking function, which expands the dynamic range of the input current without using a high-precision ADC. As shown in fig. 2, it consists of a 6-bit current digital-to-analog converter (I-DAC), a complementary comparator pair and a compensation control circuit. If the redox current is large enough to saturate the C-TIA, the I-DAC will provide the corresponding current to compensate for the additional input current, keeping the integrator in a linear state. Thus, high resolution and a large dynamic range can be achieved. The I-DAC adopts a current mirror structure and can provide a compensation current of 20 nA-1.26 muA. To accommodate input currents ranging from sub-nanoamps to a few microamps.
The current flowing into the integrator compensated by the current compensation network can be calculated as:
I in =-(I WE -I DAC );
wherein I is WE Is a redox current, I, fed into a capacitive transimpedance amplifier C-TIA DAC Is the compensation current from the 6-bit current digital-to-analog converter I-DAC.
Because the range of the redox current is large and unpredictable, the present disclosure designs an input current auto-tracking circuit to control the compensation current. To evaluate the current value, the state of the C-TIA is monitored using a complementary comparator pair.
Fig. 3 shows a circuit implementation of the I-DAC and associated control module. The control logic may be represented as:
β ctrl,n =β ctrl,n-1 +(β dir,H -β dir,L )Δβ adj
wherein beta is ctr1 Is a control signal, beta, of a 6-bit current digital-to-analog converter I-DAC dir,H Is a control signal, β, generated by an upper comparator dir,L Is a control signal generated by the lower comparator;
if the redox current is too large, above the linear range of C-TIA, the C-TIA will saturate, yielding more than V H The upper comparator will generate a high level pulse beta dir,H To trigger a 6-bit current digital-to-analog converter I-DAC to increase the unit compensation current;
otherwise, if the redox current is too small, well below the offset current, the C-TIA will produce less than V L The lower comparator will generate a high level pulse beta dir,L To trigger the 6-bit current digital-to-analog converter I-DAC to reduce the unit compensation current.
Thus, I DAC Will converge to a position closest to the redox current. At the same time, the output voltage of the C-TIA will be limited to V H And V L So that the C-TIA remains in the linear range and feeds the appropriate output to the ADC. The detectable input current range of the C-TIA extends from 40nA to 1.28 muA.
Fig. 4 and 5 show two amplifiers for measuring the redox current from a three-electrode electrochemical sensor and biasing RE to the desired voltage, respectively: a current sense amplifier and a voltage bias amplifier.
To integrate Cyclic Voltammetry (CV) mode and Chronoamperometry (CA) mode, WE was fixed at 1.2V and re was adjustable from 0.2V to 1.2V.
The input pair of the C-TIA adopts an NMOS tube design, and the input pair of the bias amplifier adopts a PMOS design.
In electrochemical methods for health monitoring, the concentration of the target analyte typically varies with the length of time from seconds to hours, which results in very low sampling frequency requirements for the redox current. In order to reduce the low frequency noise of the sense amplifier, a chopping technique is used in the C-TIA. Simulation results show that the equivalent output integral noise is 6.65 muV within the range of 0.1Hz to 10 khz.
However, in the output of the chopper amplifier, the low-frequency noise does not disappear, but is shifted to the chopping frequency. The output of the bias amplifier is directly connected to the CE of the electrochemical sensor, so it does not need to employ chopping techniques. The chopping frequency is designed in this disclosure to be 20kHz to achieve the design requirements of a 1kHz sampling rate for the sensor.
For different substances to be measured, different electrochemical sensors are required, and the electrode capacitance of the electrochemical sensors is different from several picofarads to hundreds of picofarads. The electrode capacitance directly acts as a load of the amplifier, and the stability of the amplifier is lowered. In order to improve the robustness of the amplifier to different electrode capacitances, the dual-cascode capacitance compensation is designed in the disclosure, and the sub-dominant pole of the amplifier is increased by g m r 0 And (4) replacing Miller compensation in the traditional design. After two 2pF compensation capacitors are adopted, simulation can be carried out to obtain: at a load capacitance of 350pF, the phase margin is still 63 °.
Fig. 6 and 7 show an implementation of a comparator for current compensation control.
When the output voltage of the C-TIA is close to V H Or V L When this happens, digital errors may occur, which may lead to disturbances in the compensation current. To prevent the potential compensation current disturbance problem, the present disclosure adds a preamplifier in the design of the comparator. The present design further increases the gain of the preamplifier through cross-coupled PMOS pairs. The clock signal for the subsequent latch is generated by the reset signal of the C-TIA.
Figure 8 shows the output voltage of a C-TIA, which automatically changes from the saturation region to the linear region of the C-TIA.
The potentiostat disclosed in the present disclosure is implemented using a 0.18 μm CMOS process. During testing, a 9MOhm resistor and a 100pF capacitor are connected between WE and RE in parallel, and a 1MOhm resistor and a 100pF capacitor are connected between RE and CE in parallel, so that the test scene of the three-electrode electrochemical sensor is simulated.
FIG. 9 shows the results of the output currents obtained from the SAR ADC and the compensating I-DAC, with the input redox current equal to V cell Divided by the resistor between WE and RE. The potentiostat designed by the disclosure is characterized by a current gain of 5mV/nA, a current resolution of 500pA, an input current dynamic range of 68dB, an R2 linearity of 0.9993 and a power consumption of 105 μ W.
Table 1 summarizes the performance of the potentiostat of the present disclosure and compared to the performance of the prior art potentiostat.
TABLE 1
The disclosure of the invention | |
Prior art 2 | |
Process for producing a composite material | 180nm | 180nm | 180nm |
Power consumption | 105μW | 198μW | 27.5μW |
Maximum input | 1.28μA | 1μA | 4μA |
Current resolution | 500pA | 1nA | 900pA |
Dynamic range | 68dB | 60dB | 77.95dB |
Sensing method | CA/CV | CA | CA |
Chip size | 0.47mm 2 | 1.69mm 2 | 0.36mm 2 |
The embodiments of the present disclosure have been described above. However, these examples are for illustrative purposes only and are not intended to limit the scope of the present disclosure. The scope of the disclosure is defined by the appended claims and equivalents thereof. Various alternatives and modifications can be devised by those skilled in the art without departing from the scope of the present disclosure, and such alternatives and modifications are intended to be within the scope of the present disclosure.
Claims (6)
1. A 68dB dynamic range potentiostat for electrochemical biosensing, comprising:
the device comprises a current reading circuit, a voltage bias amplifier, a current compensation network, a 12-bit analog-to-digital converter (ADC), a 10-bit digital-to-analog converter (DAC), a power management unit, an electrochemical sensor and an SPI communication module;
the current sensing circuit is connected with the current compensation network;
the power supply management unit provides system power supply voltage;
the reference voltage V output by the power management unit REF The DAC is connected with the 10-bit digital-to-analog converter;
bias voltage P output by the power management unit bias Is connected with the current compensation network;
the WE end of the electrochemical sensor is respectively connected with the current reading circuit and the current compensation network;
the bias amplifier is connected between the 10-bit digital-to-analog converter DAC and the RE end and the CE end of the electrochemical sensor; the 10-bit digital-to-analog converter DAC and the 12-bit analog-to-digital converter ADC are respectively connected with the SPI communication module; the current compensation network is connected with the SPI communication module;
the current compensation network specifically comprises:
the current compensation logic control circuit consists of a 6-bit current digital-to-analog converter I-DAC, a current compensation logic control circuit and two complementary comparators which are connected with each other;
the current sensing circuit is connected with the current compensation network through the two complementary comparators;
the 6-bit current digital-to-analog converter I-DAC is connected with a bias voltage pin of the power management unit;
the WE end of the electrochemical sensor is connected with the 6-bit current digital-to-analog converter I-DAC;
the control logic of the current compensation logic control circuit is represented as:
β ctrl,n =β ctrl,n-1 +(β dir,H -β dir,L )Δβ adj
wherein, beta ctrl Is a control signal, beta, of a 6-bit current digital-to-analog converter I-DAC dir,H Is formed byControl signal, beta, generated by the upper comparator dir,L Is a control signal generated by the lower comparator;
if the dynamic range of the redox current is within the linear range of the C-TIA, the output voltage of the C-TIA will remain at V H And V L Meanwhile, the upper comparator and the lower comparator both output low levels, and the current compensation network does not work at the moment;
if the redox current is too large, above the linear range of C-TIA, the C-TIA will saturate, yielding more than V H The upper comparator will generate a high level pulse beta dir,H Triggering a 6-bit current digital-to-analog converter I-DAC to increase the unit compensation current;
otherwise, if the redox current is too small, well below the offset current, the C-TIA will produce less than V L The lower comparator will generate a high level pulse beta dir,L To trigger the 6-bit current digital-to-analog converter I-DAC to reduce the unit compensation current.
2. The potentiometer according to claim 1, wherein the current sensing circuit is of a capacitive transimpedance amplifier (C-TIA) configuration comprising a chopper amplifier (AMP 1) and an integrating capacitor (C) F It also includes an integrating capacitor C F Switches connected in parallel for coupling the integrating capacitors C F And resetting periodically.
3. A potentiometer according to claim 1, wherein the current flowing into the integrator compensated by the current compensation network is calculated as:
I in =-(I WE -I DAC );
wherein I is WE Is a redox current, I, fed into a capacitive transimpedance amplifier C-TIA DAC Is the compensation current from the 6-bit current digital-to-analog converter I-DAC.
4. Potentiometer according to claim 2, characterized in that the integrating capacitance C of the C-TIA F Is 100pF, the C-TOutput voltage V of IA out Calculated from the formula:
where f is the frequency of the reset switch, C F Is the integrating capacitance, V, of C-TIA we Is the voltage at the WE terminal of the electrochemical sensor, I in Is the redox current fed to the capacitive transimpedance amplifier C-TIA.
5. A potentiometer according to any of claims 1 to 4, characterized in that the current sense amplifier uses chopper switches to reduce the low frequency noise of the amplifier.
6. The potentiometer according to any of claims 1 to 4, wherein the power management unit comprises a low dropout linear regulator (LDO) outputting: supply voltage VDD of 1.8V, reference voltage V used by comparator in current compensation network H 、V L Reference voltage V of DAC of 10-bit digital-to-analog converter ref And bias voltage P of current compensation network I-DAC bias 。
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